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David Notkin  Autumn 2009  CSE303 Lecture 25

David Notkin  Autumn 2009  CSE303 Lecture 25. The plan. HW7 is out; new PM due date Finish last lecture. References. type& name = variable; reference: A variable that is a direct alias for another variable. any changes made to the reference will affect the original

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David Notkin  Autumn 2009  CSE303 Lecture 25

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  1. David Notkin Autumn 2009  CSE303 Lecture 25

  2. The plan • HW7 is out; new PM due date • Finish last lecture

  3. References • type& name = variable; • reference: A variable that is a direct alias for another variable. • any changes made to the reference will affect the original • like pointers, but more constrained and simpler syntax • an effort to "fix" many problems with C's implementation of pointers • Example: int x = 3; int& r = x; // now use r just like any int r++; // r == 4, x == 4 • value on right side of = must be a variable, not an expression/cast

  4. References vs. pointers • don't use * and & to reference / dereference (just & at assignment) • cannot refer directly to a reference; just refers to what it refers to • a reference must be initialized at declaration • int& r; // error • a reference cannot be reassigned to refer to something else int x = 3, y = 5; int& r = x; r = y; // sets x == 5, r == 5 • a reference cannot be null, and can only be "invalid" if it refers to an object/memory that has gone out of scope or was freed

  5. Reference parameters returntype name(type& name, ...) { ... } • client passes parameter using normal syntax • if function changes parameter's value, client variable will change • you almost never want to return a reference • except in certain cases in OOP

  6. const and references • const: Constant, cannot be changed. • used much, much more in C++ than in C • can have many meanings (const pointer to a const int?) void printSquare(const int& i){ i = i * i; // error cout << i << endl; } int main() { inti = 5; printSquare(i); }

  7. Strings • #include <string> • C++ actually has a class for strings • much like Java strings, but mutable (can be changed) • not the same as a "literal" or a char*, but can be implicitly converted string str1 = "Hello"; // impl. conv. • Concatenating and operators string str3 = str1 + str2; if (str1 == str2) { // compares characters if (str1 < str3) { // compares by ABC order char c = str3[0]; // first character

  8. String methods string s = "Goodbye world!"; s.insert(7, " cruel"); // "Goodbye cruel world!"

  9. String concatenation • a string can do + concatenation with a string or char*,but not with an int or other type: string s1 = "hello"; string s2 = "there"; s1 = s1 + " " + s2; // ok s1 = s1 + 42; // error • to build a string out of many values, use a stringstream • works like an ostream (cout) but outputs data into a string • call .str() on stringstream once done to extract it as a string #include <sstream> stringstream stream; stream << s1 << " " << s2 << 42; s1 = stream.str(); // ok

  10. Libraries #include <cmath>

  11. Arrays • stack-allocated (same as C): type name[size]; • heap-allocated: type* name = new type[size]; • C++ uses new and delete keywords to allocate/free memory • arrays are still very dumb (don't know size, etc.) int* nums = new int[10]; for (inti = 0; i < 10; i++) { nums[i] = i * i; } ... delete[] nums;

  12. malloc vs. new

  13. Exceptions • exception: An error represented as an object or variable. • C handles errors by returning error codes • C++ can also represent errors as exceptions that are thrown / caught • throwing an exception with throw: double sqrt(double n) { if (n < 0) { throw n; // kaboom } ... • can throw anything (a string, int, etc.) • can make an exception class if you want to throw lots of info:#include <exception>

  14. More about exceptions • catching an exception with try/catch: try { double root = sqrt(x); } catch (double d) { cout << d << " can't be squirted!" << endl; } • throw keyword indicates what exception(s) a method may throw • void f() throw(); // none • void f() throw(int); // may throw ints • predefined exceptions (from std::exception): bad_alloc, bad_cast, ios_base::failure, ...

  15. C++ classes • class declaration syntax (in .h file): class name { private: members; public: members; }; • class member definition syntax (in .cpp file): returntypeclassname::methodname(parameters) { statements; } • unlike in Java, any .cpp or .h file can declare or define any class (although the convention is still to put the Foo class in Foo.h/cpp)

  16. A class's .h file #ifndef _POINT_H #define _POINT_H class Point { private: int x; int y; // fields public: Point(int x, int y); // constructor intgetX(); // methods intgetY(); double distance(Point& p); void setLocation(int x, int y); }; #endif

  17. A class's .cpp file #include "Point.h" // this is Point.cpp Point::Point(int x, int y) { // constructor this->x = x; this->y = y; } int Point::getX() { return x; } int Point::getY() { return y; } void Point::setLocation(int x, int y) { this->x = x; this->y = y; }

  18. Simple example • A Point constructor with no x or y parameter; if no x or y value is passed, the point is constructed at (0, 0). • A translate method that shifts the position of a point by a given dx and dy. // Point.h public: Point(int x = 0, int y = 0); // Point.cpp void Point::translate(intdx, intdy) { setLocation(x + dx, y + dy); }

  19. More about constructors • initialization list: alternate syntax for storing parameters to fields • supposedly slightly faster for the compiler class::class(params) : field(param), ..., field(param) { statements; } Point::Point(int x, int y) : x(x), y(y) {} • if you don't write a constructor, you get a default () constructor • initializes all members to 0-equivalents (0.0, null, false, etc.)

  20. Multiple constructors • if your class has multiple constructors: • it doesn't work to have one constructor call another • but you can create a common init function and have both call it

  21. Constructing objects • client code creating stack-allocated object: type name(parameters); Point p1(4, -2); • creating heap allocated (pointer to) object: type* name = new type(parameters); Point* p2 = new Point(5, 17); • in Java, all objects are allocated on the heap • in Java, all variables of object types are references (pointers)

  22. A client program #include <iostream> #include "Point.h" using namespace std; int main() { Point p1(1, 2); Point p2(4, 6); cout << "p1 is: (" << p1.getX() << ", " << p1.getY() << ")" << endl; // p1 is: (1, 2) cout << "p2 is: (" << p2.getX() << ", " << p2.getY() << ")" << endl; // p2 is: (4, 6) cout << "dist : " << p1.distance(p2) << endl; return 0; // dist : 5 }

  23. Client with pointers #include <iostream> #include "Point.h" using namespace std; int main() { Point* p1 = new Point(1, 2); Point* p2 = new Point(4, 6); cout << "p1 is: (" << p1->getX() << ", " << p1->getY() << ")" << endl; // p1 is: (1, 2) cout << "p2 is: (" << p2->getX() << ", " << p2->getY() << ")" << endl; // p2 is: (4, 6) cout << "dist : " << p1->distance(*p2) << endl; delete p1; // dist : 5 delete p2; // free return 0; }

  24. Stack vs. heap objects • which is better, stack or pointers? • if it needs to live beyond function call (e.g. returning), use a pointer • if allocating a whole bunch of objects, use pointers • "primitive semantics" can be used on objects • stack objects behave use primitive value semantics (like ints) • new and delete replace malloc and free • new does all of the following: • allocates memory for a new object • calls the class's constructor, using the new object as this • returns a pointer to the new object • must call delete on any object you create with new, else it leaks

  25. Why doesn't this code change p1? int main() { Point p1(1, 2); cout << p1.getX() << "," << p1.getY() << endl; example(p1); cout << p1.getX() << "," << p1.getY() << endl; return 0; } void example(Point p) { p.setLocation(40, 75); cout << "ex:" << p.getX() << "," << p.getY() << endl; } // 1,2 // ex:40,75 // 1,2

  26. Object copying • a stack-allocated object is copied whenever you: • pass it as a parameter foo(p1); • return it return p; • assign one object to another p1 = p2; • the above rules do not apply to pointers • object's state is still (shallowly) copied if you dereference/assign *ptr1 = *ptr2; • You can control how objects are copiedby redefining the = operator for your class (ugh)

  27. Objects as parameters • We generally don't pass objects as parameters like this: double Point::distance(Point p) { intdx = x - p.getX(); intdy = y - p.getY(); return sqrt(dx * dx + dy * dy); } • on every call, the entire parameter object p will be copied • this is slow and wastes time/memory • it also would prevent us from writing a method that modifies p

  28. References to objects • Instead, we pass a reference or pointer to the object: double Point::distance(Point& p) { intdx = x - p.getX(); intdy = y - p.getY(); return sqrt(dx * dx + dy * dy); } • now the parameter object p will be shared, not copied • are there any potential problems with this code?

  29. const object references • If the method will not modify its parameter, make it const double Point::distance(const Point& p) { intdx = x - p.getX(); intdy = y - p.getY(); return sqrt(dx * dx + dy * dy); } • the distance method is promising not to modify p • if it does, a compiler error occurs • clients can pass Points via references without fear that their state will be changed

  30. const methods • If the method will not modify the object itself, make the method const: double Point::distance(const Point& p) const { intdx = x - p.getX(); intdy = y - p.getY(); return sqrt(dx * dx + dy * dy); } • a const after the parameter list signifies that the method will not modify the object upon which it is called (this) • helps clients know which methods aren't mutatorsand helps the compiler optimize method calls • a const reference only allows const methods to be called on it

  31. const and pointers • const Point* p • p points to a Point that is const; cannot modify that Point's state • can reassign p to point to a different Point (as long as it is const) • Point* const p • p is a constant pointer; cannot reassign p to point to a different object • can change the Point object's state by calling methods on it • const Point* const p • p points to a Point that is const; cannot modify that Point's state • p is a constant pointer; cannot reassign p to point to a different object • (This is not one of the more beloved features of C++.)

  32. Pointer, reference, etc.? • How do you decide whether to pass a pointer, reference, or object? Some principles: • Minimize the use of object pointers as parameters.(C++ introduced references for a reason. They are safer and saner.) • Minimize passing objects by value, because it is slow, it has to copy the entire object and put it onto the stack, etc. • In other words, pass objects as references as much as possible; but if you really want a copy, pass it as a normal object. • Objects as fields are usually pointers (why not references?). • If you are not going to modify an object, declare it as const. • If your method returns a pointer/object field that you don't want the client to modify, declare its return type as const.

  33. Questions?

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